CZ2014484A3 - Biomass carrier for bioreactor - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to a biomass carrier for a bioreactor comprising a set of (1) linear fibrous structures (2) for immobilizing biomass which are joined and fixed to each other at least one linear formation (3) and / or a network of binder webs (4) on at least one surface of the system (1).

Description

Biomass carrier for bioreactor

Field of technology

The invention relates to biomass carriers for a bioreactor, in particular for a bioreactor 5 for biological wastewater treatment.

Prior art

Biological treatment is the optimal and most widespread method of removing biodegradable xenobiotics from the ecosystem and at the same time the largest 1Ό biotechnology in terms of the amount of biomass and transformed substances in general. One of the most effective methods of biological treatment is the use of biofilm applications with immobilized microorganisms in the form of biofilm reactors. The use of microorganisms capable of forming a natural biofilm offers an indisputable advantage due in particular to their generally higher resistance to toxicants and the possibility of maintaining even slow-growing microorganisms in the system. This is because the biofilm formed by extracellular polymers (especially various polysaccharides) creates a natural diffusion barrier for microorganisms within the biofilm and thus allows their proliferation even at higher concentrations of toxic substances, and at the same time increases the sorption capacity of biomass and thus higher load balancing capacity. Fixation of specific contaminant degraders in the form of natural biofilm is directly conditional not only in the case of primarily slow-growing microorganisms, but also in situations where the critical microorganism grows slowly under specific conditions (type and concentration of substrate, salinity and temperature).

For biological wastewater treatment, two types of biomass carriers are then used - fixed, which are immovably connected to the bioreactor structure, and movable, which move freely in the bioreactor in a fluidized bed and are retained in it through drainage screens.

Existing solid supports are mainly used in Fixed Bed Biological Reactor (FBBR) or Submerged Aerobic Fixed Film (SAFF) aerobic reactors.

PŠ3971CZ- while compared to the conventional activation process allow a significant increase in the amount of biomass in the system, and thus increase the existing capacity of the wastewater treatment plant, and at the same time easy system stabilization, which eliminates some potential operational problems, eg stabilization of nitrification, fiber reduction swelling, etc. Characteristic for this technology is also a very effective contact between the components of pollution contained in the water and the biofilm itself.

Solid biomass carriers are usually formed by profiled plastic formations, the disadvantage of which is especially the low surface roughness and not completely Ť (K eliminated the possibility of their overgrowth with biomass.

Movable carriers are then used mainly in reactors with moving biomass carriers (MBBR - Moving Bed Biofilm Reactor) and are formed by differently sized and differently shaped, most often inert hollow plastic bodies, which are, due to the flow of liquid in the bioreactor, in constant motion. Their 16 disadvantages are the determined density given the type of polymer and the lower rate of biofilm formation due to the morphology of their surface, especially its smoothness.

The object of the invention is to propose a new biomass carrier (fixed and mobile) for the bioreactor, which would eliminate the disadvantages of the existing carriers, and in particular enable the rapid immobilization of the biomass and possibly also its controlled growth.

2 (T

The essence of the invention

The object of the invention is achieved by a biomass carrier for a bioreactor, the essence of which consists in a system of linear fibrous structures for immobilizing biomass, which are connected and fixed to each other in fixed 2-5 pitches by at least one linear binder structure and / or a network of planar structures. at least one surface of the system. These linear fibrous formations are adapted, at least on their surface, to immobilize the biomass, and their planar or spatial arrangement can largely control the density and shape of the biofilm formed.

Biomass carrier, resp. its system of linear fibrous structures for biomass immobilization may be either planar, and may be formed, for example, by a grid of linear fibrous structures for biomass immobilization, or it may be

PS3971CZ

- 3 spatially shaped, which can be formed, for example, by rolling a flat system. In this variant, preferably at least some of the linear fiber structures for immobilizing the biomass are arranged in an overlapping or substantially overlapping manner. The spatial shape of the system of linear fiber structures for biomass immobilization can be provided by at least one linear binder structure which is connected to another linear structure, another part of the same linear structure and / or another part of the network of binder webs and / or at least parts of the web network. a binder that is connected to a linear binder structure and / or to another part of the network of planar binder structures,

IQ If the biomass carrier is intended for use as a solid biomass carrier, it is advantageous if its set of linear fibrous structures for biomass immobilization is fixed in / on a rigid flat frame.

At least some of the linear fiber structures for immobilizing biomass are formed by a core-shell type linear fiber structure in which a sheath of a polymer-containing nanofiber is fixed to the surface of the linear fiber core by wrapping at least one cover thread and / or deposited on fibers projecting above the core surface; it is associated with them by natural physical adhesion.

Another variant of the linear fibrous structure for the immobilization of biomass is then a microfibre thread, preferably an unstretched microfibre thread.

Since the biomass in question uses extracellular polymers for natural colonization, which are predominantly hydrophobic in nature, it is advantageous if the linear fibrous structures for immobilizing the biomass are provided with a hydrophobic surface layer or surface treatment, or if they are made of a hydrophobic material.

If desired, the array of biomass immobilization linear fiber structures may include reinforcing fibers and / or reinforcing linear fiber structures having a flexural stiffness greater than the flexural stiffness of the linear biomass immobilization fiber structures that provide sufficient stiffness to the biomass carrier to maintain its shape. under its load.

3Á • „. . .- s' ♦ *

PS3971EN ^J • 4 Explanation of drawings

In the accompanying drawings, Figures 1a to 1e schematically show four different embodiments of a planar variant of a biomass carrier for a bioreactor according to the invention, Figure 2 shows a spatial variant of a biomass carrier for a bioreactor according to the invention, and Figure 2a shows a cross section of the biomass carrier according to FIG. 2 in a preferred variant.

Examples of embodiments of the invention

The biomass carrier (i.e. microorganisms for biological treatment, in particular for W biological wastewater treatment) for the bioreactor according to the invention (see Figs. 1a to Fig. 2a) comprises a system 1 of linear fiber structures 2 for immobilizing biomass which are fixed at preselected spacings. at least one linear binder structure 3 applied to at least one surface of this system 1 and / or a network of planar binder sheets 4 applied to at least one surface 15 of this system 1. If this system 1 is spatially shaped (see e.g. Figs. 2 and 2a), the at least one binder linear structure 3 and / or the network of binder sheets 4 is preferably simultaneously secured in its three-dimensional shape, either only by the rigidity of the linear binder structure 3 and / or the network of binder sheets 4, and / or eg by joining at least one linear structure 3 binders 20 and / or part of a network of planar structures 4 binders with another linear structure 3 binders and / or with another part of the same linear structure 3 binders and / or with another part of the network pl ear formations 4 binders.

As a linear fibrous structure 2 for immobilizing biomass, it is possible to use in particular a linear fibrous structure 2 of the core-sheath type, the sheath of which is made of polymeric nanofibers and is fixed to the surface of the linear fibrous core by wrapping at least one covering thread (eg according to CZ PV 2009-797 ), or it is deposited on fibers protruding above the surface of the core, and is connected to them by natural physical adhesion (eg according to CZ PV 2013-694), or microfibre yarn, preferably unstretched microfibre yarn, or another linear fibrous 3U structure with similar morphology surface. Due to the specific surface morphology of these materials, the considered biomass has a high affinity for them, so it is very well captured on them (both in the case when it is applied to them in advance, and in the case where

PS3 & 71CZ '

- 5 when it is caught on them only after inserting the carrier into the bioreactor) and very willingly colonizes their entire surface, on which it forms a biofilm. Within one biomass carrier, one type of the above-mentioned linear fiber structures 2 can be used for immobilizing the biomass, or any combination of at least two of them.

Since the biomass in question uses extracellular polymers for natural colonization, which are predominantly hydrophobic in nature, it is advantageous if the linear fibrous structures 2 for immobilizing the biomass are also made of hydrophobic material and / or if the linear fibrous structures 14 2 for immobilizing the biomass are provided with hydrophobic surface treatment. In the case of linear fiber structures 2, only the sheath is sufficient for the immobilization of the core-sheath biomass, if it is made of a hydrophobic material and / or provided with a hydrophobic surface treatment.

The system 1 of reinforcing fibers and / or reinforcing linear structures 20, the flexural stiffness of which is higher than the flexural stiffness of the linear fiber structures 2 for immobilizing the biomass, and which provide the biomass carrier with sufficient rigidity, are preferably included in the system 1 of biomass immobilization linear fiber structures 2. to maintain its shape even under its load caused, for example, by hydropneumatic aeration in a bioreactor. Preferred reinforcing fibers 20 are, for example, nylon and / or polyamide fibers, etc.

A suitable binder for forming the linear binder structure (s) 3 and / or the binder sheets 4 is then, for example, a hot-melt binder based on amorphous polyolefin, ethylene vinyl acetate (EVA) copolymer, etc.

The biomass carrier in the planar variants of the embodiments shown in FIGS. 1a 25 ^- 1e is prepared by first forming a system 1 of linear fiber structures 2 for immobilizing the biomass (which, if necessary, also contains reinforcing fibers and / or reinforcing linear structures 20), and at least one linear formation 3 and / or 30 surface area 4 formed by a predetermined amount of molten binder is applied to it, at least on one side by an application device (not shown) with an application nozzle (s) and / or slot (s). This structure 3, 4, covers a preselected number of adjacent linear fiber structures 2 for the immobilization of biomass (and possibly also reinforcing fibers and / or reinforcing linear structures 20) and free spaces 5 between them, resp. in advance

PS397TCZ-6 selected part of at least one dimension of the system 1. The molten binder is preferably applied in such a way that the formed binder structure 3 is perpendicular or almost perpendicular to the longitudinal axis of most linear fiber structures 2 for immobilizing biomass, but can generally be applied under substantially at any angle to them. Depending on the nature of the linear fiber structures 2 used to immobilize the biomass (and possibly also the reinforcing fibers and / or the reinforcing linear structures 20), the molten binder penetrates at least part of their internal structure and / or coats at least part of their cross section. fixes in the set arrangement, resp. at preset intervals. At the same time, 13 its structure (s) 3, 4 simultaneously form a rigid and flexible connecting and reinforcing system which protects the system 1 of linear fiber structures 2 for immobilizing the biomass at least from the side on which it is / are applied without prevented the capture and colonization of the support by biomass or the access of treated wastewater to the deposited biofilm. At least one $ 5 linear structure 3 of binder is preferably deposited over the entire dimension of the system (see e.g. upper part of Fig. 1a and Fig. 1e), but sufficient interconnection of all linear fiber structures 2 for immobilization of biomass (and possibly reinforcing fibers and / or or reinforcing linear structures 20) can also be achieved by a group of linear structures 3 of binder, each of which is placed only on a part of its dimension 20 (see e.g. lower part of Fig. 1a), or by a network of planar structures 4 of binder. The various binder structures 3, 4 can be combined according to specific needs (see, for example, FIG. 1a and FIG. 1d).

For continuous or near-continuous production of the biomass carrier, it is advantageous if the individual linear fibrous structures 2 for immobilizing the biomass 25 and possibly also the reinforcing fibers and / or reinforcing linear structures 20 are wound on warp rolls (not shown) or stored in a container from where they are taken as required. , and are guided by their guide to the desired relative position, optionally if all or at least some of the linear fibrous structures 2 for immobilizing the biomass and / or the reinforcing fibers and / or the reinforcing linear structures 20 are wound on one common roll. During the application of the molten binder, the set 1 of linear fiber structures 2 for immobilizing the biomass (and possibly also the reinforcing fibers and / or the reinforcing linear structures 20) is preferably placed on a substrate of material to which

PS3971GZ

- 7 the applied binder has the lowest possible adhesion, such as polytetrafluoroethylene (Teflon), silicone paper, or other material with such or a similar surface. This substrate is either static and the system 1 moves relative to it, or, for example, in the form of a wall or an endless belt, moves 5 together, or carries it directly. The application device of the molten binder (one or more) is either static or movable in at least one direction of the system 1. The application of the binder then takes place either during the movement of the system 1 and / or during its interruption. In this way, a biomass carrier of the desired size and shape is formed directly, or a semi-finished product is formed from which the biomass carrier 10 of the desired size and shape is cut, cut or punched, or otherwise divided.

In another variant, the linear fibrous structures 2 for immobilizing the biomass (and possibly also the reinforcing fibers and / or the reinforcing linear structures 20) are placed in a regular, irregular or partially regular grid (see Fig. 1d), in 4K which are fixed by applying the structure (s). 3, 4 of the molten hot melt binder. These structures 4 can be planar, overlapping only the crossing points of two or more linear fiber structures 2 for immobilizing the biomass (and / or reinforcing fibers and / or reinforcing linear structures 20), so that they form a point grid (see upper and lower part in FIG. 1d), and / or at least some of them may be linear, being guided along at least part of one dimension of the system 1 (see e.g. Figs. 1a to 1e).

In order to achieve the desired mechanical properties of the formed biomass carrier 1, linear formations 3 and / or planar formations 4 of one or more 25 binders with different properties (e.g. different melting point, solidification rate, etc.) can be combined in at least one of its surfaces. .

In all the variants described above, the solidification of the applied fusible binder (s) takes place either spontaneously or is controlled, e.g. accelerated by cooling in a cooling chamber and / or a cooling medium, e.g. a stream of cooling gas (air), etc.

For deeper and / or faster penetration of the molten binder into the structure of the linear fibrous structures 2 for immobilization of biomass and / or reinforcing

PS3971CZ

- 8 fibers and / or reinforcing linear structures 20, the structures 3, 4 of this binder may be subjected to increased pressure during their application and / or after their application.

In order to prevent the possibility of tearing the linear fiber structures 2 for immobilizing the biomass and / or the reinforcing fibers and / or the reinforcing linear structures 20 from the formed carrier, it is further advantageous if the structures 3, 4 of binder or different binders are applied to both sides of the system 1. this is either in a mirror-like arrangement so that they overlap or are applied to each side in a different planar arrangement.

All linear fibrous structures 2 for the immobilization of biomass (and possibly also 1Θ reinforcing fibers and / or reinforcing linear structures 20) are arranged uniformly in constant spacings (Fig. 1a), evenly in at least two different, regularly or irregularly repeating pitches (Figs. 1b and 1d), or at different (random) pitches (Fig. 1c).

The biomass carrier 1 formed in the manner described can be used as a suitable biomass carrier 1 in a Moving Bed Biofilm Reactor (MBBR) or as a solid biomass carrier in a fixed bed / biomass reactor (FBBR). Bed Biological Reactor), in an aerobic reactor with an immersed solid biofir carrier (SAFF 20 Submerged Aerobic Fixed Film, or as a biomass carrier in hybrid bioreactor technology with combined suspension and immobilized biomass. In the first variant, 3, 4 melt formations are sufficient to achieve its sufficient rigidity binders (at least some of which are preferably located on or near its circumference), in the second variant it is advantageous if it is provided 28 with a rigid frame 6, or if it is mounted in / on the rigid frame 6 - see e.g. fig. 1e, wherein a binder can be connected to the frame 6 by means of the formations 3, 4.

The above-described planar biomass carrier can further be spatially shaped in any of its variants, e.g. by folding it and / or folding it into the desired shape and / or rolling it, or otherwise, thereby forming a spatial biomass carrier. Fig. 2 shows a three-dimensional biomass carrier formed by winding a flat biomass carrier formed in the manner described above into a formation whose cross-section has a spiral shape due to the layering of the flat biomass carrier. Because in this variant they were linear

PS397-1CZ

- 9 fibrous structures 2 for the immobilization of biomass of the planar biomass carrier fixed at the same spacings, fill the space of the spatial biomass carrier unevenly, resp. irregularly. In a variant of the embodiment shown in Fig. 2a, the linear fibrous structures 2 for immobilizing the biomass in the initial planar biomass carrier are arranged with a continuously changing spacing, so that after coiling they are in overlaps or substantially overlaps (indicated by dashed lines). This variant is particularly advantageous in cases of high biomass production, since the biomass is captured only on the linear fiber structures 2 and is formed along them into lamellae, between which there is free space. This prevents the biomass carrier from being completely filled with biomass and at the same time significantly increases the surface area of the final biofilm. The three-dimensional shape of the biomass carrier is ensured either only by the rigidity of the linear binder structure 3 and / or the binder web 4 and / or, for example, by connecting at least one linear binder structure 3 and / or part of the binder web 4 with another linear binder structure 3. and / or with another part of the same linear structure 3 binders and / or with another part of the network of sheets 4 binders.

In another variant for the production of a spatially shaped biomass carrier according to the invention, this carrier is prepared by fixing a pre-spatially shaped system of linear fiber structures 2 for immobilizing biomass (and optionally 2.0 reinforcing fibers and / or reinforcing linear structures 20) deposited in a designated form; preparation, at least one linear structure 3 of binder and / or a network of sheets 4 of binders.

The spatially shaped biomass carrier can be used in particular as a mobile biomass carrier in a moving biomass carrier reactor (MBBR 2 © Moving Bed Biofilm Reactor), or as a biomass carrier in hybrid bioreactor technology with both suspended and immobilized biomass. However, when arranged in a planar arrangement (formed, for example, by folding or assembling the initial biomass carrier), it can also serve as a solid biomass carrier in a Fixed Bed Biological 30 Reactor (FBBR) or in an aerobic reactor with an immersed solid biofir carrier. (SAFF - Submerged Aerobic Fixed Film). In such a case, it is advantageous if it is provided with a rigid frame or if it is stored in / on a rigid frame.

’’ * PS3971CZ ·

Particularly in the case of mobile biomass carriers according to the invention, it is advantageous if their final density after biofilm growth is as close as possible to the density of wastewater (approx. 900 to 1200 kg / m ³ ), so that they do not sediment at the bottom of the bioreactor or agglomerate at the surface. wastewater.

5r The biomass carrier shown in Fig. 2 was formed in such a way that with a parallel arrangement of polyester (PL) yarns 176 f 36 * 1 ^χ 3 provided with a sheath formed by a layer of polyurethane (PII) nanofibers according to CZ PV 2009-797, arranged at regular intervals of 6 mm and polyamide 6 (PA 6) fibers with a diameter of 0.45 mm, arranged at 18 mm intervals and guided in respective 10 'gaps between the three polyester yarns, formed a set of linear fiber structures 2 for immobilizing biomass with a width of 300 mm. Perpendicular to the linear fiber structures 2 for immobilizing biomass over the entire width of the system 1, at regularly alternating intervals of 5 mm and 25 mm, linear structures 3 of molten binder based on amorphous polyolefin with an AZ temperature of 165 ° C, each with a specific weight 2 g / m. During the spontaneous cooling of the molten binder to the ambient temperature, it solidified and, as a result, the system 1, resp. its linear fibrous structures 2 for immobilizing the biomass and the reinforcing fibers 20 in a set arrangement. The semi-finished product thus formed was subsequently divided in width into strips (strips) 30 mm wide and 20,300 mm long. The division was always performed in the free space between the linear formations of the fusible binder 5 mm apart, so that the edges of the penetrated strips (strips) were formed by these linear formations 3. The strips (strips) thus prepared were subsequently rolled lengthwise and fixed by melting the ends of the linear formations. 3 of the hot-melt binder and their connection to the linear structures 3 of the hot-melt binder 25 in the previous layer. The shape of this biomass carrier is ensured in two axes by tight winding of the linear formations 3 made of hot-melt binder and in the third axis parallel to the axis of this formation by reinforcing polyamide fibers.

Claims (13)

PATENT CLAIMS Biomass carrier for a bioreactor, characterized in that it comprises an assembly (1) which comprises linear fibrous structures (2) for immobilizing 5-biomass and reinforcing fibers and / or reinforcing linear fibrous structures (20) whose flexural stiffness is higher than the flexural stiffness of the linear fiber structures (2) for immobilizing the biomass, wherein the linear fiber structures (2) and the reinforcing fibers and / or the reinforcing linear fiber structures (20) are joined and fixed to each other at fixed spacings by at least one linear structure (3). and / or a network of sheets (4) of binder deposited on at least one surface of the system (1). Biomass carrier according to Claim 1, characterized in that the system (1) of linear fiber structures (2) for immobilizing the biomass is planar. Biomass carrier according to Claim 1 or 2, characterized in that the system (1) of linear fibrous structures (2) for immobilizing the biomass is formed by a grid of linear fibrous structures (2) for immobilizing the biomass. Biomass carrier according to any one of claims 1 to 3, characterized in that the assembly (1) is fixed in / on a rigid surface frame (6). Biomass carrier according to Claim 1, characterized in that the system (1) 20 of linear fiber structures (2) for immobilizing the biomass is spatially shaped. Biomass carrier according to Claim 5, characterized in that the system (1) of linear fiber structures (2) for immobilizing the biomass is formed by a planar system (1) wound into a three-dimensional structure, the at least one linear binder structure (3) forming a spiral. . Biomass carrier according to Claim 5 or 6, characterized in that at least some of the linear fiber structures (2) for immobilizing the biomass are arranged in an overlapping or substantially overlapping manner. Biomass carrier according to any one of claims 5 to 7, characterized in that at least one linear binder structure (3) is connected and / or at least a part of the network of planar binder structures (4) is connected to another linear structure (3), to another PV 2014-484 “’ PS3971EN-1 Biomass carrier according to any one of the preceding claims, characterized in that at least some of the linear fibrous structures (2) for immobilizing the biomass are formed by a linear fibrous structure (2) of the core shell type, in which the shell containing polymer nanofibers is fixed to the linear surface. of the fiber core by wrapping at least one cover thread. Biomass carrier according to any one of the preceding claims, characterized in that at least some of the linear fibrous structures (2) for immobilizing the biomass are formed by a core-sheath fiber structure (2) in which the sheath containing polymeric nanofibers is deposited on above the surface of the core, and is associated with them by natural physical adhesion. Biomass carrier according to Claim 9 or 10, characterized in that the 45 nanofibers are formed from a hydrophobic polymer. 7/11/2014 12 & 2015 - 12 - part of the same linear structure (3), and / or to another part of the network of planar structures (4) binders, thus ensuring the spatial shape of the system (1) of linear fiber structures (2) for immobilization of biomass. Biomass carrier according to any one of the preceding claims, characterized in that at least some of the linear fiber structures (2) for immobilizing the biomass are formed by a microfiber yarn, preferably an unstretched microfiber yarn. 2Q Biomass carrier according to one of the preceding claims, characterized in that the linear fibrous structures (2) for immobilizing the biomass are made of a hydrophobic material and / or are provided with a hydrophobic surface treatment.